KR101557876B1 - Fuel cell system having improved starting performance in low temperature and Operating method thereof - Google Patents

Abstract

The present invention relates to a fuel cell system, and more particularly, to a system for preheating a cooling system as a means for stably starting and / or operating a fuel cell system in a low temperature (below 0 ° C) And a second preheater capable of raising the internal temperature of the fuel cell system to improve the low temperature startability of the fuel cell system.
According to the present invention, since the fuel cell stack cooling system is operated in a low temperature environment (0 ° C or less) by using a preheater, stable system operation is possible, and a first preheater and an air preheater, (BOP), the stack and the pure water can be heated within a time period required for raising the temperature to the temperature necessary for the reforming reaction, so that it is effective for operation in a low-temperature environment (0 DEG C or less) of the fuel cell.

Description

TECHNICAL FIELD [0001] The present invention relates to a fuel cell system having improved low-temperature startability and a method of operating the fuel cell system.

The present invention relates to a fuel cell system, and more particularly, to a system for preheating a cooling system as a means for stably starting and / or operating a fuel cell system in a low temperature (below 0 ° C) And a second preheater capable of raising the internal temperature of the fuel cell system to improve the low temperature startability of the fuel cell system.

The present invention also relates to a method of operating a fuel cell system that stably starts and / or operates a fuel cell system in a low-temperature (below 0 ° C) environment.

A polymer electrolyte fuel cell system produces electrical energy from an electrochemical reaction in a fuel cell stack. In the fuel cell stack, hydrogen is separated into hydrogen ions and electrons in the catalyst of the anode, separated hydrogen ions are passed to the cathode through the polymer electrolyte membrane in the stack, It combines with the electrons entering the air electrode to generate water and generate electric energy.

The fuel cell stack is provided with a separator plate having a flow path for supplying a fuel gas and an oxidizer gas to the electrodes and a flow path for cooling water for maintaining an operating temperature of the fuel cell. Plate or the like is used.

Further, the fuel cell system includes a fuel processing apparatus (reforming apparatus) using a hydrocarbon-based raw material as an apparatus for producing hydrogen required for operation. The fuel treatment apparatus (reforming apparatus) usually uses steam reforming (SR) and auto-thermal reforming (ATR). In order to reform the fuel, a reforming catalyst and a hydrocarbon- Raw materials are needed and pure water must be supplied constantly.

The pure water should generate steam for smooth reaction. The above-mentioned auto-thermal reforming (ATR) method has a difference in that oxygen is supplied in air as a raw material.

The gas generated by the reforming catalyst is subjected to water-gas shift (WGS) as a means for removing CO, reacted with CO gas in the selective oxidation reaction unit (PROX) and oxygen in the air, The hydrogen-containing gas. Also, unreacted hydrogen is burned and discharged through an anode offgas oxidizer (ATO). It is advantageous to remove CO by installing a cooling device and a water trap between the water gas conversion reaction (WGS) and the selective oxidation reaction (PROX).

Also, peripheral devices such as pumps, valves, and sensors for the movement and thermal management of the material of the fuel cell system are included and controlled so that the fuel cell system can operate stably.

For stable operation in the fuel cell system, water management other than fuel supply and heat management is important. Water (condensation water, condensate) is present in various locations in the system. For example, water is present to keep the polymer electrolyte membrane in a humidified state during operation of the fuel cell, and water is generated by an electrochemical reaction at the cathode of the fuel cell during power generation. During fuel cell power generation, heat is generated in the fuel cell, and the cooling water circulates in order to form uniform operating temperature conditions and reaction conditions.

Pure water is required for the reforming reaction in the fuel processing apparatus for producing hydrogen in the fuel cell system, and hydrogen in the generated gas electrochemically reacts in the electrode layer in the fuel cell stack.

The generated gas contains carbon dioxide and moisture in addition to hydrogen. In the fuel cell system, the humidified gas and air are frozen in a low-temperature environment below 0 DEG C, and therefore must be discharged through the purge when the fuel cell system is stopped.

The number of dew condensation remaining in the fuel electrode channel, the cathode channel and the membrane electrode assembly (MEA) is difficult to start due to freezing in a low temperature (below 0 ° C) environment.

In addition, when the fuel cell is placed in a state of being free from operation for a long time, the residual moisture is frozen to block the gas flow path, thereby interfering with the supply of the fuel gas and the oxidizing gas to the electrode including the gas diffusion layer, .

Therefore, in order to operate the fuel cell in a state where the fuel cell system is located below the freezing point for a long time, stable operation can be performed only if the inner ice is thawed first.

1. Korean Patent Publication No. 10-2009-011925 2. Korean Patent No. 10-1172841 3. Korean Patent No. 10-0893431 4. Korean Patent Publication No. 10-2006-0033522

 The present invention has been proposed in order to solve the problems raised in the above background art, and it is an object of the present invention to provide a first preheater (first preheater) which preheats a cooling system as means for stably starting and operating a fuel cell system in a low temperature A first preheater and a second preheater capable of raising the internal temperature of the fuel cell system are used. The first preheater uses a coolant which is not frozen at a low temperature, and a gasoline combustion method The present invention provides a fuel cell system with improved low-temperature startability, which can raise the temperature of the coolant to overcome the low-temperature environment of the fuel cell and stably operate the fuel cell system, and its operation method.

In addition, the second preheater is a gasoline combustion type, which improves the internal temperature of the fuel cell system by raising the temperature of the incoming air, overcomes the low temperature environment, and improves the low temperature startability of the fuel cell system Fuel cell system and a method of operating the same.

In order to achieve the above-mentioned object, the present invention provides a fuel cell system including a first preheater, which is a device for preheating a cooling system as a means for stably starting and operating the fuel cell system in a low temperature (below 0 ° C) The first preheater uses a coolant which is not frozen at a low temperature and uses a gasoline combustion method to raise the temperature of the coolant to thereby increase the temperature of the fuel The present invention provides a fuel cell system with improved low-temperature startability and a method of operating the fuel cell system to overcome the low-temperature environment of the battery and enable stable operation of the fuel cell system.

In the fuel cell system with improved low temperature startability,

A fuel cell stack for generating electrical energy by generating electrical energy by reaction of hydrogen and oxygen;

And a fuel cell stack connected to the fuel cell stack to generate a reformed gas containing hydrogen by reforming reaction of fuel, pure water, and air, and supplying the reformed gas to the fuel cell stack A fuel treatment device for performing a fuel injection;

A pure water tank connected to the fuel treatment device to supply the pure water to the fuel treatment device;

A membrane humidifier connected to the fuel cell stack for supplying air to the fuel cell stack;

A first preheater for defrosting at least one of the pure water tank, the fuel processor, and the fuel cell stack using an antifreeze;

An antifreeze tank storing the antifreeze; And

And a second preheater for heating the internal temperature by using the internal cold air.

The fuel processor includes an auto-thermal reforming (ATR) unit that performs a reforming reaction by supplying fuel and air; A water-gas shift (WGS) unit that removes CO produced by the reforming reaction; A selective oxidation reaction unit which reacts with CO gas and oxygen in the air to supply a gas containing hydrogen to the fuel cell stack; An anode tailgas oxidizer (ATO) for burning and discharging unreacted oxygen; And a water-gas shift (WGS) unit; A heat exchanger for exchanging heat between the selective oxidation reaction subunits; And a temperature sensor for sensing the units.

At this time, an electric heater for the ATR reaction unit and the WGS reaction unit is installed.

The secondary battery module includes a secondary battery module for charging the generated electric energy. The secondary battery module is defrosted at a low temperature by using a coolant heated by the first pre-heater, And the battery is charged when the power is generated.

The outlet of the first pre-heater may be connected to a branch pipe, and the branch pipe may include a first pipe for thawing the pure water tank and a second pipe for thawing the secondary battery module .

Further, the pure water tank may have a heat exchanger structure for internal thawing.

In addition, the pure water tank may be characterized in that the inlet of the pure water supply pump and the connection pipe of the pure water tank are composed of a double pipe through which the antifreeze can flow.

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The stacked coolant pump is connected to the pure water tank, and the first preheater circulates the warmed antifreeze solution to the stack cooling system to thaw the condensation water and condensation water of the fuel electrode and the air electrode of the fuel cell stack .

In addition, the first preheater is characterized in that the heated antifreeze liquid dissolves the pure water tank through the first pipe and the antifreeze is circulated through the second pipe to the enclosure of the secondary battery module.

Also, the first pre-heater and the second pre-heater are preheating devices capable of burning in a low-temperature environment, and the exhaust gas is generated using a gasoline combustion method.

In addition, a circulation pump may be installed inside the first preheater, and may have a cooling water inlet, a cooling water outlet, an air inlet, and an exhaust outlet.

In addition, a blower may be installed inside the second preheater, and may have an air inlet, an air outlet, an air inlet, and an exhaust outlet.

In addition, the second preheater may be configured to dry condensate on the inner peripheral device and the pipe surface at a low temperature of the fuel cell.

In addition, a pure water supply pump and a condensate water valve, which are thawed by the exhaust gas from the second pre-heater, may be included in the form of an exhaust gas duct.

Also, the exhaust gas of the second pre-heater defrosts the outside of the membrane humidifier and a membrane humidifier is located in the exhaust gas duct, and the pure water pump, the condensate pump, and the membrane humidifier are positioned and defrosted irrespective of order .

The heat exchanger may further include a radiator for supplying heat generated in the heat exchanger to the antifreeze tank.

On the other hand, another embodiment of the present invention is a fuel cell system with improved low temperature startability as described above,

a) cold-starting the fuel cell system;

b) preheating and defrosting the first preheater and the second preheater;

c) the fuel cell stack is developed as the fuel sagging device and the fuel cell stack operate as the preheating and thawing are performed; And

d) maintaining the fuel cell system at ambient temperature; The fuel cell system comprising: a fuel cell system;

At this time, the step (b) includes: (b-1) operating the first pre-heater to increase the temperature of the antifreeze tank and the secondary battery module and defrost the pure water tank; b-2) operating the third pre-heater to raise the internal temperature of the fuel cell system; b-3) Fuel Treatment Apparatus A method of operating a coolant pump to defrost a fuel treatment apparatus; b-4) thawing the fuel cell stack by operating the stack coolant pump; And b-5) determining the thawing by checking the set temperature.

Also, the steps b-1) and b-2) may be performed simultaneously, and then the steps b-3) and b-4) may be simultaneously performed.

The step b-5) may include activating the first pre-heater and the second pre-heater when the fuel cell system is started up; Detecting an increase in the temperature of the antifreeze tank and determining whether the temperature of the antifreeze tank reaches a set temperature; Operating the fuel processor coolant pump and the stack coolant pump to defrost the pure feed double tube, the fuel processor, and the fuel cell stack of the fuel processor; And determining that thawing has occurred if the pure tank temperature, the stack cooling water outlet temperature, and the fuel cell system internal temperature are equal to or higher than a predetermined value; And a control unit.

In addition, the step c) includes: c-1) operating the fuel processing apparatus; And c-2) charging the secondary battery module with the power generated according to the fuel cell stack; And a control unit.

Further, the step (b-5)) includes the steps of operating an electric heater of the fuel processor; Performing on / off control of the electric heater and waiting for the temperature of the reaction units to rise to a set temperature; Opening the bypass valve to supply fuel, pure water, and air when the set temperature is reached; Waiting for a certain time for stabilizing the hydrogen supply when the temperature of the autotuning reaction (ATR) unit, the temperature of the gas shift converter (WGS) unit, and the temperature of the selective oxidation reaction unit become the set temperature; Opening the inlet valve and the outlet valve for supplying the stack hydrogen, and closing the bypass valve; Applying an initial current to the fuel cell stack; Confirming the temperature rise of the stack air inlet and charging the secondary battery module with the target current value; And a control unit.

In the step d), the preheater is stopped when the outlet temperature of the stacked cooling water is equal to or higher than a first predetermined temperature, and restarted when the outlet temperature is lower than a first predetermined temperature to maintain the temperature at room temperature. And a second preheater for stopping the second preheater when the temperature of the second preheater is higher than a predetermined second temperature. When the internal temperature reaches a predetermined third predetermined temperature, the second preheater is activated And maintaining the internal temperature at room temperature.

At this time, the first predetermined temperature is 45 ° C, and the third predetermined temperature is 5 ° C.

According to the present invention, since the fuel cell stack cooling system is operated in a low temperature environment (0 ° C or less) by using a preheater, stable system operation is possible, and a first preheater and an air preheater, (BOP), the stack and the pure water can be heated within a time period required for raising the temperature to the temperature necessary for the reforming reaction, so that it is effective for operation in a low-temperature environment (0 DEG C or less) of the fuel cell.

Further, as another effect of the present invention, by using an antifreeze as a cooling medium that does not freeze at a low temperature, it is possible to prevent physical breakage due to freezing at a low temperature (0 DEG C or less), and by arranging a peripheral device in a discharge path of gasoline combustion exhaust gas, A malfunction due to a stable operation of a water pump, a valve type, a BOP, and the like necessary for hydrogen production of the processing apparatus can be cited.

1 is a schematic view of a fuel cell system 1 having a thawing structure according to an embodiment of the present invention.
Fig. 2 is a schematic view of an embodiment showing the concept of raising the temperature of the fuel cell system 1 shown in Fig. 1 by using an antifreeze to thaw.
3 is a schematic view of another embodiment showing the concept of thawing the pure water passage to the thawing of the fuel cell system 1 shown in Fig.
4 is a schematic perspective view of the first preheater 4 in the fuel cell system 1 shown in Fig.
5 is a schematic perspective view of the second preheater 6 in the fuel cell system 1 shown in Fig.
6 is a schematic view showing a double pipe structure 620 of the pure water tank 303 in the fuel cell system 1 shown in FIG.
Figure 7 is a schematic view of the dual tubular structure 620 shown in Figure 6.
8 is a flowchart showing a low-temperature start-up and start-up process of the fuel cell system according to an embodiment of the present invention.
9 is a flowchart showing a preheating process as a step of the flowchart shown in FIG.
FIG. 10 is a flow chart showing the starting and developing process as two steps of the flowchart shown in FIG.
11 is a flow chart showing the process of maintaining the room temperature of the fuel cell system in three steps of the flowchart shown in FIG.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for similar elements in describing each drawing.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The term "and / or" includes any combination of a plurality of related listed items or any of a plurality of related listed items.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Should not.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a fuel cell system with improved low-temperature startability according to an embodiment of the present invention and a method of operating the fuel cell system will be described in detail with reference to the accompanying drawings.

1 is a schematic view of a fuel cell system 1 having a thawing structure according to an embodiment of the present invention. 1, the fuel cell system 1 includes a secondary battery module 302; A fuel cell stack 2 for supplying electric energy generated by generating electrical energy by reaction of hydrogen and oxygen to the secondary battery module 302; A fuel cell stack 2 connected to the fuel cell stack 2 to generate a reformed gas containing hydrogen by a reforming reaction of fuel, pure water and air, A fuel processing device (3) for supplying the fuel cell stack (2); A pure water tank 303 connected to the fuel treatment device 3 to supply the pure water to the fuel treatment device 3; A membrane humidifier (10) connected to the fuel cell stack (2), for supplying air to the fuel cell stack (2); A first preheater 307 for defrosting the secondary battery module 302, the pure water tank 303, the fuel processor 3, and the fuel cell stack 2 using an antifreeze; An antifreeze tank (5) for storing the antifreeze; And a second preheater (6) for raising the internal temperature using internal cold air.

In addition, the fuel cell system 1 includes a first preheater 4, which is a device for preheating the cooling system as a means for stably starting and / or operating, and a second preheater 6 capable of raising the internal temperature of the fuel cell system And the like.

The fuel cell system 1 includes a fuel processor 3 and uses pure water to perform a reforming reaction. Since the pure water freezes at a low temperature (0 ° C or less), the pure water preheated by the first preheater 4 is circulated inside the pure water tank 303 to dissolve the ice. Of course, the antifreeze tank 5 for storing such antifreeze is constituted.

Accordingly, the antifreeze liquid discharged from the antifreeze tank 5 by the first pre-heater 4 passes through the outlet port of the pure water tank 303. The outlet is a pipe on the inlet side of the pure water supply pump 202 for supplying pure water to the fuel treatment device 3 and the warmed antifreeze has a structure for melting the inlet pipe of the pure water supply pump 202, 3). Here, the pure feed pump 202 may be a metering pump.

In order to smoothly charge and discharge the secondary battery module 302 at a low temperature (below 0 ° C), the antifreeze supplied from the first pre-heater 4 passes through the enclosure of the secondary battery module 302 Thereby raising the temperature of the secondary battery module 302.

Also, the first pre-heater 4 uses a gasoline combustion method. Therefore, the combustion exhaust gas generated by the first pre-heater 4 is supplied to the stacked hydrogen inlet valve 401, the hydrogen outlet valve 402, the by- The valve 403 is defrosted.

In addition, a pure water supply pump 202 for supplying the pure water valve (404) used in the fuel cell system (1) and pure water required for the reforming reaction (otherwise referred to as a fixed water quantity) So that the combustion exhaust gas of the second pre-heater (6) is supplied to the inlet pipe of the pump and the valve thawing duct (306) so as to have the structure of the valve thawing duct (306).

At this time, a double pipe 203 is installed between the pump and valve defrosting duct 306 and the fuel processor 3. [ That is, a pipe through which pure water is supplied from the pure water tank 304 to the fuel processing apparatus 3 through the pure water supply pump 202 and the antifreezing liquid which is preheated through the fuel processor coolant pump 201 is circulated.

The exhaust gas supplied to the pump and valve throttling duct 306 is discharged to the outside by defrosting the condensate valve 404 and the pure water supply pump (metering pump) 202.

When the antifreeze is raised to a certain temperature by using the first pre-heater 4 when the fuel cell system 1 is started at a low temperature (0 ° C or less), the cooling water for cooling the stack cooling water pump 103 and the fuel processor 3 Fuel Treatment System The cooling water pump 201 is driven to enable smooth operation during startup in a low-temperature environment through thawing of the fuel processor 3 and / or peripheral devices including the fuel cell stack 2.

The fuel processor 3 includes an auto-thermal reforming (ATR) unit 31 for performing a reforming reaction by receiving fuel and air, a water gas conversion reaction a selective oxidation reaction unit (37) for supplying a gas containing hydrogen to the fuel cell stack (2) by reacting the CO gas with oxygen in the air, a water-gas shift (WGS) unit An anode tailgas oxidizer 35 for burning and discharging the exhaust gas and an optional oxidation reaction unit 37 and a heat exchanger 35 for heating the water between the water gas shift (WGS) unit 32 and the selective oxidation reaction unit 37 And a heat exchanger 33 for exchanging heat.

(Not shown) constituted of an electric heating device (electric heater) (not shown) is provided in the fuel processing apparatus 3, and the pure water used for the fuel treatment and the reactors (ATR, WGS, Prox) is heated to a predetermined temperature. Of course, an electric heating device such as an ATR reactor unit electric heater, a WGS reactor unit electric heater, or the like may be separately constructed.

Heat generated in the heat exchanger 33 is supplied to the antifreeze tank 5 through the radiator 7 to preheat the antifreeze tank 5. [

Further, the fuel cell stack 2 produces electrical energy by an electrochemical reaction. In the fuel cell stack 2, hydrogen is separated into hydrogen ions and electrons in the catalyst of the anode 21, and the separated hydrogen ions are separated from the air electrode (cathode) through the polymer electrolyte membrane 22 in the fuel cell stack 23 and the oxygen 104 supplied to the air electrode 23 through the membrane humidifier 10 combines with electrons entered into the air electrode through an external lead to generate water while generating electrical energy. Here, the fuel cell system 1 may be a polymer electrolyte fuel cell system.

In order to facilitate discharging / charging in a low-temperature environment of 0 ° C or less, the secondary battery module 302 must be rapidly heated to supply power necessary for defrosting in a low-temperature environment.

In order to facilitate discharging / charging in a low-temperature environment of 0 ° C or lower, the secondary battery module 302 needs to rapidly raise the temperature in a low-temperature environment to supply power necessary for defrosting. The circulation pump 307 in the first preheater 4 is constructed so that the first pipe 304 extending from the outlet to the pure water tank 303 and the second pipe 308 extending to the secondary battery module 302 are branched do.

The antifreeze heated by the first preheater 4 is used to thaw the pure water tank 303 through the first pipe 304 and the secondary battery module 302 is thawed through the second pipe 308 Discharge the power consumption.

The circulation pump 307 in the first preheater 4 is constructed by branching the first pipe 304 from the outlet to the pure water tank 303 and the second pipe 308 from the outlet to the pure water tank 303 and to the secondary battery 302.

The exhaust gas from the first pre-heater 4 and the second pre-heater 6 is supplied to the pure water supply pump 202, the hydrogen inlet valve 401 of the fuel cell stack 2 of the fuel cell system 1, (402), a bypass valve (403), and a condensate valve (Drain) (404).

In the fuel cell system 1 including the fuel processor 3 and the first preheater 4, power consumed for preheating, power generation, and maintenance of the room temperature is supplied to the secondary battery module 302, .

The exhaust gas from the first pre-heater 4 dissolves the hydrogen inlet valve 401, the hydrogen outlet valve 402 and the bypass valve 403, and the exhaust gas from the second pre- Pump 202, and condensate valve (Drain) 404 are thawed.

The exhaust pipe 311 of the second pre-heater 6 is installed inside the pump and the valve throttling duct 306 configured to allow the combustion exhaust gas to flow into the pure water supply pump (metering pump 202) and the condensate valve (Drain) .

The operation of the circulation pump 201 of the fuel processing apparatus 3 and the operation of the stack cooling water pump 103 for circulating the cooling system of the fuel cell stack 2 result in the pure tank 303 temperature, It is desirable to defrost the fuel cell stack 2 hydrogen supply valve and the condensate system valve through the exhaust gas while the temperature is achieved.

The fuel cell system 1 also includes a control unit (not shown), which is composed of a microprocessor, a memory, and the like, and performs a control function.

In addition, a temperature sensor (not shown) is provided for sensing the temperature of the components constituted in the fuel cell system 1. Sensing information of the temperature sensor is transmitted to a control unit (not shown).

Fig. 2 is a schematic view of an embodiment showing the concept of raising the temperature of the fuel cell system 1 shown in Fig. 1 by using an antifreeze to thaw. That is, FIG. 2 shows the principle of thawing the antifreeze by circulating the antifreeze by the second preheater 4. 2, when the heat of the heat exchanger 33 is radiated by the radiator 7 to preheat the antifreeze liquid in the antifreeze tank 5, the preheated antifreeze liquid is supplied to the pure water tank 303 by the first preheater 4, And the secondary battery module 302 to raise the temperature of each component. Of course, the first pre-heater 4 is provided with an internal circulation pump 307 for circulating the antifreeze liquid.

The preheated antifreeze liquid in the antifreeze tank 50 is circulated through the fuel processor 3 and the fuel cell stack 2 by the fuel processor cooling water pump 201 and / Lt; / RTI >

3 is a schematic view of another embodiment showing the concept of thawing the pure water passage to the thawing of the fuel cell system 1 shown in Fig. That is, FIG. 3 shows the principle of thawing the hot air by circulating the hot air by raising the internal temperature by using the second pre-heater 6. Referring to FIG. 3, the second pre-heater 6 preheats the internal cold air by using combustion exhaust gas, converts it into hot air, and supplies it to the inlet pipe of the pump and valve throttling duct 306 .

Exhaust gas supplied to the pump and valve throttling duct 306 is discharged to the outside by defrosting the condensate valve 404 and the pure water supply pump 202.

4 is a schematic perspective view of the first preheater 4 in the fuel cell system 1 shown in Fig. 4, the first pre-heater 4, which is a gasoline combustion device capable of burning at a low temperature (below 0 ° C), includes a combustion air inlet 430, a combustion gas outlet 431, a coolant inlet 440, A coolant outlet 441, and a fuel supply pump 450, and the like. Accordingly, it is possible to provide the first pre-heater 4 in the fuel cell system to preheat the coolant system.

Of course, the first preheater 4 internally includes an internal circulation pump 307 and a gasoline combustor (not shown), and supplies fuel to the gasoline combustor (not shown) by the fuel supply pump 450. Of course, gasoline is commonly used as fuel.

Accordingly, a coolant that does not freeze at a low temperature (below 0 DEG C) in the fuel cell system is used, and a coolant preheated at a low temperature is circulated in the cooling water system to defrost components constituting the fuel cell system.

5 is a schematic perspective view of the air preheater 6 in the fuel cell system 1 shown in Fig. In addition, by providing the second preheater 6 in the fuel cell system 1, it is very effective in overcoming the low temperature (below 0 캜) environment of the components of the fuel cell system 1 through the internal temperature raising. The second preheater 6 is a device including a gasoline combustor and a gasoline fuel supply pump and supplies a heat source for thawing the fuel cell system 1 at a low temperature. 5, the second pre-heater 6, which is a combustible gasoline combustor, is provided with a combustion air inlet 530, a combustion gas outlet 531, an air inlet (or a cold air inlet) 510, (Or warm air outlet) 511, a fuel supply pump 450, and the like.

Therefore, the second pre-heater (6) is provided in the fuel cell system (1) and the internal temperature is maintained at room temperature. Of course, a gasoline combustor (not shown) is formed inside the second preheater 6, and the fuel is supplied to the gasoline combustor (not shown) by the fuel supply pump 450

FIG. 6 is a schematic view showing a double pipe structure 620 of the pure water tank 303 in the fuel cell system 1 shown in FIG. 1, and FIG. 7 is a schematic view of the double pipe structure 620 shown in FIG. 6 and 7, in the fuel cell system 1, the piping between the metering pump outlet pipe serving as the pure water supply pump 202 and the fuel treatment apparatus 3 constitutes a double pipe 203 structure. Therefore, when the coolant pump 201 of the fuel processing apparatus 3 is operated, the pure water passage 710 in the dual pipe 203 flows into the bypass pipe 630 through the antifreezing agent inlet 630 and the antifreezing agent outlet 631, It is thawed. In this case, since the pure water is not frozen, the fuel is supplied smoothly to the fuel treatment device 3.

8 is a flowchart showing a low-temperature start-up and start-up process of the fuel cell system according to an embodiment of the present invention. 8 is broadly divided into one to three stages, and the outline of these steps is as follows.

1) Step 1: Preheating and thawing steps

Step 1-1: Operation of the first preheater (4) and thawing by antifreeze (S800, S820, S821)

In the fuel cell system 1 having the first preheater 4, the operation of the first preheater 4 at a low temperature (0 ° C or lower) is performed in a coolant tank 5 The antifreeze in the antifreeze tank 5 is heated in the first preheater 4 and flows through the branch pipe 301 and the first pipe 304 into the pure tank internal heat exchanger and the double pipe 305) and circulates to the antifreeze tank (5). And the pure water tank 303 and pure tank double pipe are thawed while raising the antifreeze to a predetermined temperature.

The antifreeze is heated in the first preheater 4 and is circulated to the secondary battery module 302 through the branch pipe 301 and the second pipe 308. The antifreeze is used to defrost the secondary battery 302 Thereby performing a process of discharging electric power necessary for starting the fuel cell at a low temperature (0 DEG C or less).

       Steps 1-2: Operation of the second preheater (6) and thawing by internal heating (S800, S810, S811)

In the fuel cell system 1 having the second preheater 6, the second preheater 6 is operated at a low temperature (0 ° C or lower) to maintain the internal temperature of the fuel cell system 1 at room temperature.

Warm air (warm wind) is generated by the second pre-heater 6 in the interior of the fuel cell system 1, and the internal pipes, valves, pumps, and control air are thawed by the warm air, And drying the surface condensed water of the internal parts of the fuel cell system 1 that occurs during the low-temperature environment.

       (3) thawing (S825) by the operation of the coolant pump (201)

When the coolant of the antifreeze tank 5 reaches a certain temperature, the fuel cell system 1 is operated to operate the coolant pump 201 of the fuel cell system 1 so that the pure water required for the reforming reaction Which is a supply pipe of the double pipe 203, is defrosted.

The fuel processor 3 includes an autothermal reforming reactor (ATR) unit 31, a water gas shift reactor (WGS) unit 32, a heat exchanger 33, a selective oxidation reactor (Prox) (WGS) unit 32 and a selective oxidation reactor (PROX) unit 37 are connected to a heat exchanger (not shown) 33 to effectively remove CO. When the fuel processor cooling water pump 201 operates, cooling water circulates in the heat exchanger.

The fuel processor cooling water pump 201 circulates the dual pipe 203 which is a supply pipe to the outlet of the pure water supply pump 202 of the fuel processing apparatus 3 using a coolant as cooling water.

Pure water is supplied to the inside of the fuel cell stack to supply pure water for the reforming reaction and a coolant flows to the outside through the double pipe 203 and defrost the fuel cell stack 3.

       Steps 1 to 4: Thawing of the fuel cell stack 2 by operation of the stack cooling water pump 103 (S823)

When the antifreeze liquid in the antifreeze tank 5 reaches a predetermined temperature as the thawing step of the fuel cell stack 2, the stack coolant pump 103 of the fuel cell system 1 is operated, Circulates the cooling passage inside the stack 2 and passes through the radiator 7. [ It is possible to prevent the MEA damage from developing the fuel cell system 1 at a low temperature by defrosting the residual dew condensation number in the flow path between the fuel electrode and the air electrode through the circulation of the cooling flow path inside the fuel cell stack 2. [

       Steps 1-5: Determination of thawing of the fuel sagging device 30 and the fuel cell stack 2 (S830)

 This first step will be described later with reference to Fig.

 2) Phase 2: Maneuvering and Development Phase

        Step 2-1: Operation of the fuel processor 3 by thawing and supply of hydrogen and air to the fuel cell stack 2 (S840, S850, S860)

(ATR, WGS, Prox) for operating the electric heating device (electric heater) and treating the pure water and the fuel used for the fuel treatment when the target temperature of the first stage is reached as the starting step of the fuel processing device 3 ) Is heated to a predetermined temperature.

When the temperature of each element reaches a predetermined target value and maintains a steady state, fuel, pure water and air necessary for the reaction are supplied to the fuel processor 3 at a predetermined set value. The bypass valve 403 of the supply pipe connected to the fuel cell stack 2 in the fuel processing apparatus 3 is opened to keep the intermediate product generated in the fuel treatment process (reforming reaction process) from being supplied to the fuel cell stack 2 And the exhaust gas is discharged through the anode tail-gas oxidizer (ATO). It is determined that the reforming catalyst reactor temperature reaches the set temperature and the hydrogen gas can be stably supplied to the fuel cell stack 2 at a predetermined time,

        Step 2-2: Power is generated by the fuel cell stack 2 to charge the secondary battery module 302 (S870)

The hydrogen gas is supplied to the fuel cell stack 2 as the step of generating the fuel cell. The hydrogen gas is supplied to the fuel cell stack 2 when the bypass valve 403 is closed and the hydrogen inlet valve 401 and the hydrogen outlet valve 402 of the fuel cell stack 2 are opened. Current is applied and the secondary battery 302 is charged at the same time as power generation.

These two steps will be described later with reference to FIG.

3) Step 3: Fuel cell system (1) Maintaining the room temperature

         Step 3-1: Maintaining the room temperature by the first preheater 4 (S880, S890)

In the fuel cell system 1, when the fuel cell stack 2 is made to generate electricity, the fuel cell stack 2 can maintain a normal temperature by the reaction heat. Therefore, it is preferable to control the first pre-heater 4 so that the temperature of the antifreeze tank 5 can be maintained at room temperature and prevent excessive fuel consumption. The first preheater 4 stops the first preheater 4 when the temperature of the cooling water outlet of the fuel cell stack 2 reaches 45 ° C or more, desirable

         Step 3-2: Maintaining the room temperature by the second preheater 6 (S880, S891)

The air preheater 6 controls the internal temperature of the fuel cell system 1 to be maintained at room temperature and operates when the internal temperature of the fuel cell system 1 falls below 5 ° C, It is preferable to control so as not to descend.

The air preheater 6 senses the internal temperature of the fuel cell system 1 when the temperature of the air preheater 6 is increased and stops the air preheater 6 when the temperature reaches a predetermined temperature of the room temperature. So that the internal temperature of the fuel cell system 1 is maintained at room temperature.

In the fuel cell system 1 having the fuel processor 3 and the first preheater 4, power consumed for the operation of the first to third stages is supplied to the secondary battery 302 .

These three steps will be described later with reference to FIG.

9 is a flowchart showing a preheating process as a step of the flowchart shown in FIG. In the first stage, the preheating and defrosting of the pure water tank 303 and the internal temperature by the preheating devices in the fuel cell system 1 including the first preheater 4 and the second preheater 6 to be.

9, when the first pre-heater 4 and the second pre-heater 6 are operated in a low-temperature (below 0 ° C) environment, the antifreeze is circulated so that the temperature TC of the antifreeze tank 5 and the temperature TC of the pure water tank 303 (Step S900, step S910, step S920).

If the antifreeze tank temperature TC is equal to or higher than the initial set temperature TT1, the first preheater 4 is stopped, and if the antifreeze tank temperature TC is less than the initial temperature TT1, the coolant pumps 103 and 201 are operated. The coolant pump 201 and the stack coolant pump 103 are operated at a temperature (TD) of the pure water tank 303 of 40 ° C or higher, for example, to cool the fuel processor 3 and the fuel cell stack 2 (Steps S930, S931, S940, and S950).

The second preheater 4 is stopped when the stack cooling water outlet temperature TS becomes equal to or higher than the defrosting determination temperature TT2 (for example, 5 deg. C), and restarted when the defrosting determination temperature TT2 is lowered (Steps S960, S961, S970).

When the second preheater 6 is operated in a low temperature (0 ° C or less) environment, the second preheater 6 is stopped when the temperature of the fuel cell system 1 reaches a predetermined temperature of the room temperature, 2 preheater 6 to start the internal temperature of the fuel cell system 1 at room temperature.

Therefore, the temperature TD of the pure water tank 303, the outlet temperature TS of the stack cooling water and the internal temperature TA of the fuel cell system 1 are respectively set to a predetermined value It is determined that the fuel cell system 1 is defrosted when the defrosting determination temperature TT2 is equal to or higher than the defrosting determination temperature TT2.

FIG. 10 is a flow chart showing the starting and developing process as two steps of the flowchart shown in FIG. 10 is a flowchart showing the operation of the electric heating device (electric heater) when the target temperature of the first stage described in Fig. 9 is reached as the starting step of the fuel processing apparatus 3, The temperatures TR and TW of the reactors ATR, WGS and Prox are heated to a predetermined temperature (steps S1000, S1001, S1003 and S1005). Where TR is the ATR temperature and TW is the WGS temperature.

The bypass valve 403 of the supply pipe connected to the fuel cell stack 2 in the fuel processing apparatus 3 is opened to keep the intermediate product generated in the fuel treatment process (reforming reaction process) from being supplied to the fuel cell stack 2 And is exhausted through the anode tail-gas oxidizer (ATO) (S1007, S1009).

It is determined that the reforming catalyst reactor temperatures TR, TW, TP and TB reach the respective set temperatures and that the hydrogen gas can be stably supplied to the fuel cell stack 2 at a predetermined time, (S1011, S1013).

The hydrogen gas is supplied to the fuel cell stack 2 as the step of generating the fuel cell. Hydrogen gas is supplied to the fuel cell stack 2 when the bypass valve 403 is closed and the hydrogen inlet valve 401 and the hydrogen outlet valve 402 of the fuel cell stack 2 are opened. (Step S1015, step S1017, step S1019, step S1021, step S1023, step S1025) in which the secondary battery 302 is charged simultaneously with the power generation.

In addition, in the power generation of the fuel cell system 1, air is supplied to the air electrode and an initial predetermined current is applied to the fuel cell stack 2 to generate an exothermic reaction, Which is more effective in starting at low temperatures (below 0 ° C).

In the fuel cell system 1, the stack air supply pipe 104 and the air outlet pipe 105 constitute a membrane humidifier 10, and the temperature of the air inlet rises due to the reaction heat. Therefore, when the temperature of the inlet of the air electrode rises after the application of the predetermined predetermined current, the current value of the fuel cell stack 2 is controlled to the target value while operating.

11 is a flow chart showing the process of maintaining the room temperature of the fuel cell system in three steps of the flowchart shown in FIG. Referring to FIG. 11, in the fuel cell system 1, when the fuel cell stack 2 is powered up, the fuel cell stack 2 is maintained at room temperature by the reaction heat (steps S1100 and S1110).

The first pre-heater 4 stops the first pre-heater 4 when the coolant outlet temperature TS of the fuel cell stack 2 reaches a predetermined temperature of 45 ° C or higher. When the temperature is lower than a predetermined temperature, the first pre- And is maintained at room temperature (step S1120).

Therefore, it is preferable that the first pre-heater 4 controls the temperature TC of the antifreeze tank 5 to be maintained at room temperature and prevents excessive fuel consumption.

The second pre-heater 6 controls the internal temperature of the fuel cell system 1 to be maintained at room temperature. When the internal temperature of the fuel cell system 1 falls below 5 ° C, the second pre-heater 6 is operated. Or less. Accordingly, when the temperature of the second pre-heater 6 is raised, the second pre-heater 6 is stopped when the temperature of the fuel cell system 1 is sensed at the predetermined temperature of the room temperature, The control unit 6 activates the internal temperature of the fuel cell system 1 at the normal temperature (step S1130).

1 ... Fuel cell system
2 ... Fuel cell stack
3 ... Fuel treatment device (reforming device)
4 ... first preheater
5 ... antifreeze tank
6 ... second preheater
7 ... radiator
10 ... just humidifier
21 ... anode
22 ... insulating film
23 ... air electrode
31 ... auto-thermal reforming (ATR) unit
32 ... water-gas shift (WGS) unit
33 ... heat exchanger
35 ... anode Anode tail gas oxidizer (ATO)
37 ... selective oxidation reaction unit
101 ... hydrogen supply pipe
102 ... hydrogen outlet piping
103 ... Stack Cooling Pump
104 ... air supply pipe
105 ... air outlet pipe
201 ... Fuel Treatment Equipment Cooling Pump
202 ... pure feed pump
203 ... double tube
204 ... antifreeze circulation passage
205 ... reforming reactor
206 ... reformer internal heat exchanger
207 ... pure supply passage
301 ... antifreeze distributor
302 ... secondary battery module
303 ... pure tank
304 ... 1st piping
304 ... pure tank internal heat exchanger and double pipe
306 ... Pump and valve thaw duct
307 ... internal circulation pump
308 ... second piping
309 ... valve thaw duct
310 ... Pre-heater exhaust pipe
311 ... air preheater exhaust pipe
401 ... Hydrogen inlet valve
402 ... hydrogen outlet valve
403 ... Bypass valve
404 ... Condensate Valve (Drain)

Claims (25)

A fuel cell stack for generating electrical energy by generating electrical energy by reaction of hydrogen and oxygen;
And a fuel cell stack connected to the fuel cell stack to generate a reformed gas containing hydrogen by reforming reaction of fuel, pure water, and air, and supplying the reformed gas to the fuel cell stack A fuel treatment device for performing a fuel injection;
A pure water tank connected to the fuel treatment device, supplying pure water to the fuel treatment device and having a heat exchanger structure for thawing therein;
A membrane humidifier connected to the fuel cell stack for supplying air to the fuel cell stack;
The temperature of the antifreeze tank storing the antifreezing liquid at low temperature is raised to circulate the heated antifreeze liquid to charge the electric energy, and the temperature of the rechargeable battery module is raised to defrost the heated antifreeze liquid to the heat exchanger structure to defrost the pure water tank, A fuel processor, and a first preheater for defrosting the fuel cell stack; And
And a second preheater for heating the internal temperature using internal cold air,
A pure water supply pump for supplying pure water of the pure water tank and a condensate water valve for discharging the condensed water to be defrosted by the exhaust gas by the second preheater are disposed adjacent to each other in the duct structure,
A plurality of valves connected between the fuel processor and the fuel cell stack to be thawed by the exhaust gas by the first preheater are disposed in the duct structure,
Wherein the first pre-heater and the second pre-heater generate exhaust gas using a gasoline combustion system as a preheating device capable of burning in a low-temperature environment,
The method according to claim 1,
The fuel processing apparatus includes:
An auto-thermal reforming (ATR) unit that performs a reforming reaction by supplying fuel and air; A water-gas shift (WGS) unit that removes CO produced by the reforming reaction; A selective oxidation reaction unit which reacts with CO gas and oxygen in the air to supply a gas containing hydrogen to the fuel cell stack; An anode tailgas oxidizer (ATO) for burning and discharging unreacted oxygen; And a water-gas shift (WGS) unit; A heat exchanger for exchanging heat between the selective oxidation reaction subunits; And a temperature sensor for sensing the units. ≪ Desc / Clms Page number 20 >
3. The method of claim 2,
Wherein an electric heater for the autothermal reforming reaction unit and the water gas shift reaction unit is installed.
delete The method according to claim 1,
Wherein an outlet of the first preheater is connected to a branch pipe and the branch pipe has a first pipe for thawing the pure water tank and a second pipe for thawing the secondary battery module. Fuel cell system.
delete The method according to claim 1,
Wherein the pure water tank is composed of a double pipe through which an antifreezing solution can flow through an inlet of a pure water supply pump and a pure water tank connection pipe.
delete The method according to claim 1,
Wherein the stacked coolant pump is connected to the pure water tank, and the first preheater circulates the warmed antifreeze to the stack cooling system to thaw the condensation water and the condensation water of the fuel electrode and the air electrode of the fuel cell stack. Fuel cell system. The method according to claim 1,
Wherein the first preheater defrosts the pure water tank through the first piping and the defrosting liquid circulates through the second piping to the enclosure of the secondary battery module. system.
delete The method according to claim 1,
Wherein the circulation pump is installed inside the first pre-heater, and has a cooling water inlet, a cooling water outlet, an air inlet, and an exhaust outlet.
The method according to claim 1,
Wherein the blower is installed inside the second preheater and has an air inlet, an air outlet, an air inlet, and an exhaust outlet.
The method according to claim 1,
And the second preheater is configured to dry the condensed water on the inner periphery and the piping surface at a low temperature of the fuel cell.
delete The method according to claim 1,
Wherein the exhaust gas from the second pre-heater defrosts the outside of the membrane humidifier and a membrane humidifier is located in the exhaust gas duct, and the pure water pump, the condensate pump, and the membrane humidifier are positioned and defrosted irrespective of order. Fuel cell system.
3. The method of claim 2,
Further comprising a radiator for supplying heat generated in the heat exchanger to the antifreeze tank.
An improved low temperature startability according to any one of claims 1 to 3, 5, 7, 9 to 10, 12 to 14, 16 and 17 A method for operating a fuel cell system,
a) cold-starting the fuel cell system;
b) preheating and defrosting the first preheater and the second preheater;
c) the fuel cell stack is developed as the fuel sagging device and the fuel cell stack operate as the preheating and thawing are performed; And
d) maintaining the fuel cell system at ambient temperature;
And operating the fuel cell system.
19. The method of claim 18,
The step b)
b-1) operating the first pre-heater to increase the temperature of the antifreeze tank and the secondary battery module and defrost the pure tank;
b-2) operating the third pre-heater to raise the internal temperature of the fuel cell system;
b-3) Fuel Treatment Apparatus A method of operating a coolant pump to defrost a fuel treatment apparatus;
b-4) thawing the fuel cell stack by operating the stack coolant pump; And
b-5) determining thawing by checking the set temperature;
And operating the fuel cell system.
20. The method of claim 19,
Wherein the steps b-1) and b-2) are simultaneously performed, and then the steps b-3) and b-4) are simultaneously performed.
20. The method of claim 19,
The step (b-5)
Activating the first preheater and the second preheater when the fuel cell system is started;
Detecting an increase in the temperature of the antifreeze tank and determining whether the temperature of the antifreeze tank reaches a set temperature;
Operating the fuel processor coolant pump and the stack coolant pump to defrost the pure feed double tube, the fuel processor, and the fuel cell stack of the fuel processor; And
Determining that thawing has occurred if the temperature of the pure tank, the outlet temperature of the stack cooling water, and the internal temperature of the fuel cell system are equal to or greater than a predetermined value; And operating the fuel cell system.
19. The method of claim 18,
The step c) comprises the steps of: c-1) operating the fuel processor; And c-2) charging the secondary battery module with the power generated according to the fuel cell stack; And operating the fuel cell system.
20. The method of claim 19,
The step b-5)
Operating an electric heater of the fuel processor;
Performing on / off control of the electric heater and waiting for the temperature of the reaction units to rise to a set temperature;
Opening the bypass valve to supply fuel, pure water, and air when the set temperature is reached;
Waiting for a certain period of time for stabilizing the hydrogen supply when the temperature of the autotuning reaction (ATR) unit, the temperature of the gas shift reaction (WGS) unit, and the temperature of the selective oxidation reaction subunit become the set temperature;
Opening the inlet valve and the outlet valve for supplying the stack hydrogen, and closing the bypass valve;
Applying an initial current to the fuel cell stack;
Confirming the temperature rise of the stack air inlet and charging the secondary battery module with the target current value; And operating the fuel cell system.
19. The method of claim 18,
The step d)
Stopping the preheater when the outlet temperature of the stacked cooling water becomes a predetermined first predetermined temperature or more and restarting the furnace when the temperature of the outlet reaches the first predetermined temperature, And
When the temperature of the second pre-heater is increased, the internal temperature of the fuel cell system is sensed. When the second pre-heater reaches a predetermined second temperature, the second pre-heater is stopped. When the internal temperature is lower than a third predetermined temperature, And maintaining the internal temperature at a normal temperature.
25. The method of claim 24,
Wherein the first predetermined temperature is 45 ° C, and the third predetermined temperature is 5 ° C.

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